Grooving tool



April 3, 1951 G. H. LEONARD 2,547,915

. GROOVING TOOL Filed July 28, 1948 5 Sheets-Sheet l INVENTOR 34 9202 2 H Leonard G. H. LEONARD GROOVING TOOL April 3, 1951 5 Sheets-Sheet 3 Filed July 28, 1948 INVENTOR e H. Leonard April 3, 1951 G. H.-LEONARD 2,547,915

GROOVING TOOL rued July 28, 1948 5 Sheets-Sheet 4 ATTO April 3, 1951 G. H. LEONARD 2,547,915

r V GROOVING TOOL Filed July 28, 1948 5 Sheets-Sheet 5 INVENTOR EYS Patented Apr. 3, 1951 GROOVING TOOL George H. Leonard, Darien, C. G. S. Laboratories, Inc.,

Conn., assignor to Stamford, Conn.

Application July 28, 1948, Serial No. 41,079

2 Claims.

This invention relates to machine tools for performing cutting operations, and more particularly to grooving tools for cutting internal grooves in bores; such grooves being commonly used for holding lock rings or similar devices in position.

The problem of cutting internal grooves has been 'a source of annoyance, both to those concerned with quantity production and to the machinists doing miscellaneous job shop work. In

- the first instance, the process of cutting grooves in bores of small diameter is one that is relatively diflicult and expensive. In the case of the small machine shop, one of the most serious problems results from the fact that the machinist is called upon to cut grooves of various widths and depths in bores of widely varying diameters. Thus, he may be called upon to purchase a particular grooving tool for a single job, with little, if any likelihood of future need for the tool. In

either case, it may be necessary to frequently reobject is to effect such movement during the cut ting operation automatically by pressure of the work against the tool.

Another object is to provide such a cutting too1 including provision for burring, that is, removing the raised edges of the groove, while the groove is being cut.

In another aspect of the invention, it is an object to provide such a grooving tool which is readily adapted for cutting grooves at various depths and in a wide range of bore diameters. Another object is to provide such a grooving tool which is rugged in construction and well balanced so that centrifugal forces do not interfere with proper operation of the tool.

Still another object is to provide such a grooving tool which may be adjusted quickly for different diameters of bore; the cutting blade maintaining automatically the desired radial alignment.

A further object is to provide such a grooving tool in which the various moving parts are protected against damage from chips or other foreign material. 7

Still a further object is to provide such a grooving tool incorporating calibrated scales to 2 indicate the proper setting for cutting grooves in bores of different diameters.

Another object is to provide such a tool in which the various adjustments, for example, radial groove depth, distance between the groove and the end of the bore, and the adjustments relating to the diameter of the bore, may be made and controlled with precision. I

The invention, accordingly, consists in the features of construction, combinations of elements, and arrangements of parts; the various features of novelty which characterize the present invention being pointed out with particularity in the claims set forth herewith. For a better understanding of the invention, its advantages and the specific objects obtained with its use, reference should be had to the following description and to the accompanying drawings, in which:

Fig. 1 is an elevational view of a grooving tool embodying certain features of the present invention;

Fig. 2 is an enlarged sectional view taken on line 22 of Fig. 1;

Fig. 3 is a partial sectional view similar to Fig. 2 but showing the groove cutting and burring blades in extended position;

Fig. 4 is a sectional view taken on line 4-4 of Fig. 2;

Fig. 5 is a sectional view taken on line 5-5 of Fig. 3;

Fig. 6 is an elevational view of a modified form of grooving too1;

Fig. 7 is an enlarged sectional view taken on line 'l! of Fig. 6;

Fig. 8 is a partial sectional view taken on line S-8 of Fig. 7;

Fig. 9 is a sectional view taken on line 99 of Fig. '7;

Fig. 10 shows, in perspective, still another grooving tool embodying the invention;

Fig. 11 shows an enlarged axial section through the grooving tool shown in Fig. 10;

Fig. 12 is a sectional view taken along line l2|2 of Fig. 11;

Fig. 13 is a bottom view of the grooving tool shown in Fig. 10 taken along line l3--I3 of Fig. 11;

Fig. 14 is a sectional M-M of Fig. 1;

Fig. 15 is a sectional view taken along line |5-l5 of Fig. 11;

Fig. 16 is a sectional Iii-46 of Fig. 11;

Fig. 1'? is a longitudinal sectional view taken along line I1-|1 of Fig. 11;

Fig. 18 is a perspective view of the shank holder and guide pillars of the tool shown in Figs. 10

view taken along line view taken along line Fig. 19 is a perspective view of the cutter barrel of the same tool;

Fig. 20 is a perspective view of various component parts of the pilot and bearing assembly of the same tool;

Fig. 21 shows, in perspective, the shank holder, retainer ball, pilot body, cutting blade, and blade retracting spring of the same tool;

Fig. 22 is a perspective view of the adjusting ring of the same tool;

Fig. 23 is a perspective view of the cutter barrel of the same tool;

Fig. 24 is a perspective view of components utilized for locking in position the cutter barrel shown in Fig. 23; and

Fig. 25 is a partial sectional view of the tool shown in Fig. 11 with ,a difierent pilot for internally-grooving a ,bore of smaller diameter.

In the embodiment of the invention illustrated in Figs. 1 to 5, a grooving tool, generally indicated at 2, is adapted to cut an internal groove and to remove simultaneously any projecting edges or burrs from the area adjacent the groove. In addition, the construction is such that sidewise bending moments are avoided, so that the portion of the tool within the bore transmits only torque about the longitudinal axis of the tool.

The burring is accomplished by a burring blade 4-(Figs. 2 and 3) which comprises a length of flat tool steel with a cutting edge 6, which extends outwardlynear one end of the blade, and a T-shaped portion 8 at the opposite end.

The groove is cut by groove-cutting blade I2, which has at one end a groove-cutting edge H1 and at theopposite end a T-shaped portion (not shown) similar to the T-shaped portion 8 of the burring blade 4. The cutting blade I2 is flat, similarto the burring blade both pieces, for example, being stamped from fiat sheets of tool stock; the desired cutting edges being subsequentl hardened, and ground to the desired dimensions and shape. The burring blade 4 and thecutter blade l2 are arranged with their fiat sides adjacent and extend longitudinally along a slot! 6 formed in the tool body i8,-which extends the full length of the grooving tool 2, with their cutting edges extending radially outwardly in opposite directions.

Such .blades are inexpensive to fabricate and may be replaced easily in the tool, thus minimizing the operating cost. For example, to cut grooves of various widths, it is necessary only to replace the relatively inexpensive cutting blade [2 with a difierent one that has been ground to the desired dimensions.

These cutting edges are recessed normally within the slot ll; of the tool body l8, and are extended radially therefrom in order to perform the grooving and burring operations. To this end a pin 22 (see also Fig. 5), having head portions 24, is secured in the tool body l8 and extends crosswise of the slot I8, through the slot 26 in the burring blade 4 and the slot 28 in the cutting blade l2. Each of these slots is provided with an enlarged opening 32 at one end to permit removal of the blades; the opposite ends of the slots being of uniform width, but having a portion which extends at an angle with respect to the longitudinal axis of the blades. Thus, slot 26 has an end portion extending at an angle toward the right as seen in Fig. 2, whereas slot 28 has an angular portion extending toward the left as seen in that figure. It is apparent that relative longitudinal motion between the blades and [2 with respect to the pin 22 will cause simultaneous extension of the burring edge 6 and the groove-cutting edge [4.

The burring and cutting edges are extended, of

course,.after the leading portion of the grooving tool has been inserted the proper distance within the bore; the distance between the groove-cutting edge It and the outer end of the bore remaining constant while the groove cutting blade is being extended and retracted. To this end, the tool body l8 and its slot l6 are arranged to move longitudinally with respect to the burring blade 4 and the groove-cutting blade l2; this movement is accomplished by the following described structure.

- A pilot 34 is mounted rotatably and extends within a sealed thrust bearing, generally indicated at 38, havinganinner, portionifi and.;an outer portion 42, which is, surrounded by .a;tubu-. lar bearin sleeve it, formed integrally with'an upwardly extending bearing sleeve extension ,46 of reduced diameter. The pilotfil .is provided with a tapered portion 48, which is adapted to enter the end of the bore in which. the groove is to be cut, surrounded bya smooth shoulder 52 with which the faceof the workpiece abuts.

The extension 4i: of the bearing sleeve 44 is secured to a sleeve 5-3, which is mounted coaxially within the tubular extension 46, by a set screw 55, the body of which extends through a longitudinal slot 58 in the tubular extension 46.

The undersides of the shoulders, formed by the T-shaped ends of the burring and groove-cutting blades 4 and I2, abut the upper end ;of sleeve 54; the blades being pressed firmly in contact with the sleeve 54 by means of a blade-retracting spring 62,-which is maintained in compression be tween the ends of blades 4 and I2 and the end of a bore 5 3 in a mounting sleeve 68, which is secured to tool bodyl8 by a'set screw 12.

It is understood, of course, that-relative rotation must be provided between the workpiece and the body 18 of the-grooving tool, and that the rotary power maybeapplied to either.

Thus, if the tool body;l8 isgripped firmlyby-a chuck, or other suitable source of rotative power,

. and the opposite end of the grooving tool isinserted within a bore which is to .be internally grooved, so that'the face of the workpiece rests against shoulder 52 of the pilot 36, extension of the groove-cutting edge !4 and burring-edge 6 may be accomplished by exerting longitudinal force on the tool body l8, causing the toolbody 8 to move further into the bore of the workpiece. The blades cannot follow this movement because they are restrained by the sleeve 54 which is secured to the pilot 34 abutting the face of the workpiece. Accordingly, the cross pin 22 moves inwardly of'the, bore with the tool body l8;to whichit is secured and is caused to traverse the sloping portions of the slots 26-and 23 in the burring and groove cutting blades. The camming action of the pin against the sloping surfaces of the respective slots causes the groove-cutting edge 14 and the burring edgefi to be extended-simultaneously, as shown in Fig. 3.

It is apparent that this arrangement has sev-,

eral desirable features. For example, if the ;work

piece is not chucked too tightly with respect-"tov the grooving tool 2; so-that some lateral deviation is possible, the groove-cutting blade "l21and the burring blade 4 will provide a self-centering action through the medium of the pin .22. The burring blade is-not intended to cut into thezwall of thegroove and; accordingly, is wider ,andzusuey rod I4 is mounted slidably within a longitudinal bore 76 in the tool body I8, the upper end of the bore being closed by an adjusting screw 18 in threaded engagement therewith. As the longitudinal force is applied to the tool body I8, to extend the groove-cutting blade I4, the spring 62 is compressed by the relative movement between the mounting sleeve 68 and the groovecutting and burring blades I2 and 4. This movement is limited by the adjusting rod 14 which extends between the inner surface of the adjusting screw 18 and the upper ends of blades 4 and I2 when the groove cutting edge is fully extended. Thus, the radial depth of the groove depends upon the position of adjusting screw I8,

which may be locked in position, for example, by a set screw 82.

In order to adjust the distance within the bore at which the groove is cut, it is necessary only to adjust the distance between the shoulder 52 of the pilot 34 and the groove cutting edge I 4. This is accomplished by loosening the set screw 56 (Figs. 2 and 4) which extends through a longitudinal clearance slot 84 in the mounting sleeve 68 and through the slot 58 in extension 46, moving extension 46 and, accordingly, the pilot 34, longitudinally with respect to the sleeve 54 and the tool body I8 until the desired distance between the cutting edge I4 and the shoulder 52 is obtained. The set screw 56 is then re-tightened, locking the sleeve 54 to the extension 46.

Figs. 6 to 9 show a modified grooving tool 2B particularly adapted for grooving bores of small diameter. Accordingly, the burring arrangement has been eliminated to decrease the diameter of the apparatus which must be inserted within the bore.

A groove cutting blade I2B, with a cutting edge I 4B and a T-shaped upper portion I02, is formed from a flat sheet of tool steel material, for example, by stamping; the cutting edge I4B subsequently being hardened and ground. The cutting blade I2B is mounted within a longitudinal slot IEB extending lengthwise of a tool body I8B.

In order to extend the cutting edge I4B during the cutting operation, a cam surface I 04 is formed at the lower end of the slot "EB and co- (Fig. 7) provided operates with a similar sloping cam surface or heel on the cutting blade I2B, directly opposite the cutting edge I4B. Thus, relative longitudinal movement of the tool body I8B with respect to the blade I2B will cause the cutting edge I4B to project from the slot the magnitude of the movement.

In order to hold the cutting blade I2B in position and to cause the cutting edge I 4B to be retracted into the tool body IBB when the cutting operation has been completed, a coil spring 623, which surrounds a portion of the tool body IBB, is held in compression between the upper surface or the T-shaped portion I02 of the cutting I63 in accordance with Accordingly,

' a bearing sleeve 44B, within 6 blade I 23 and a shoulder I06 on the tool body I8B; the lower surfaces of T-shaped portion I02 resting on a shoulder I08 formed on the inner surface of a sleeve I I2. Advantageously, the upper surface of the T-shaped portion I02 is formed at an angle so that the spring 623 applies greater force to the right-hand side of the cutting blade I2B, as viewed in Fig. '7, thus insuring that the cutting edge I4B will be retracted fully.

As in the previous example, the distance between the cutting edge I43 and the shoulder 52B of the pilot 34B remains fixed during the cutting operation, and the tool body IBB moves inwarde 1y of the bore to extend the cutting edge I 4B. this is accomplished by applying force to the tool body IBB in the direction of the bore, thus, causing the tool body to move longitudinally within the sleeve I I 2, compressing the spring 623, and sliding cam surface I84 forwardly with respect to the cutting blade IZB to extend the cutting edge I4B. This movement is limited by an adjusting rod MB, as in the embodiment previously described.

The pilot 34B is in threaded engagement with which the tool body I8B is supported rotatably by radial bearings I I4 and H6 and a conventional type thrust bearing H8.

The bearingv sleeve 44B is secured to a clamping sleeve I22 by means of a wire detent spring I24, one end of which has a semi-circular shape and is adapted to fit within a circular ring groove I26 on the inner surface of the bearing sleeve MB. The detent spring I24 rests in a longitudinal slot I28 in clamping sleeve I22; the center portion of the detent spring resting against a fulcrum or raised portion in the slot I23, as at I29, and the opposite end being retained by a screw I32-which extends across the slot I28 as shown in Fig. 6, and which screw serves also to clamp the sleeve I22 securely to the outer surface of sleeve II2. Thus, bearing sleeve 44B is rotatable with respect to the clamping sleeve I22 (the end of spring I24 traversing the groove I26), but is not free to move longitudinally with respect thereto. It is apparent that tire tool may be rapidly disassembled by simply pulling oiT the bearing sleeve 443.

In order that the tool body I813 can move longitudinally within sleeve II2, which is secured to clamping sleeve I22, and at the same time prevent rotary movement between the tool body IBB and the sleeve I I2, a ball I34 (Fig. 8) rests in a suitable opening I36 in the tool body I83 and extends into a longitudinal slot I 38 in sleeve I I2; thus, locking sleeve II 2 and body I8B together for rotary motion, but permitting body I8B to move longitudinally within the sleeve II2.

To prevent chips from entering the bearing structure, a sealing ring I42 (Figs. 7 and 9) is provided between the pilot 34B and the radial bearing IIB. Sealing ring I42 is provided with a spiral slot I44 and a tongue portion I 46, which is adapted to extend into the slot IGB to form a seal along that horizontal portion of the slot not occupied by the cutting blade IZB. Because of the slot I44, the tongue I46 is supported resiliently by the ring I42, so that it can be forced outwardly by the blade [2B as the cutting edge I4B is extended from the slot IGB.

In order to further insure that chips do not interfere with proper operation of the tool, a portion of the tool body I8B adjacent the cutting edge MB is cut away, as at I48, in Fig. 6.

Figures 10 to 25 show still another embodiment of the invention in the form of a-grooving-tool 20, which is adapted for cutting grooves in bores of various diameters. The general construction of thecutting blade control mechanism has been adapted to permit incorporating the adjustable features.

A groove-cutting blade 12C (Figs. 11 and 21) having a cutting edge MC is mounted in-a-iongitudinal slot IBC in a tool body iSC. A-ball 2%2 rests within a transverse opening in the cutter blade=|8C adjacent thecuttingedge MC and ex tends therefrom into a channel 222 extending through the tool body I8C at an angle',-for example, 45 degrees, to the longitudinal axis of the tool body. In operation, the ball 282traversesthe channel 264 to extend and retract the cutting edge I4C. In Fig. 11, the grooving tooi 2C is shown with the cutting edge partially extended in order to portray the construction more clearly.-

To anchor the cutting blade 12C in a fixed position, a projection 286 is provided at its upper end, and extends into a circular groove 288 in a cutter barrel 2|2.

A spring 620 surrounds a portion of the tool body IBC within the cutter barrel H2 and is held in compression between the surface of a shoulder 244 in the cutter barrel 212 (see also Fig. 23), and the end of a tool body extension 216 which is press-fitted to a knurled end'2i8 of tool body IBC. The tool body extension 216 is secured, as will be described below, to atool head portion generally indicated at 222 which is movable longitudinally with respect to the cutter barrel 212. Thus, as in the above described embodiments, the tool body N30 is movable with respect to the cutting blade IZC to extend and retract the groove-cutting edge 14C.

The radial depth of the groove to be cut is regulated by means of an adjusting ring 224 (Figs. 11 and 22) slidably surrounding the upper end of cutter barrel 2l2 and in threaded engagement with a shank holder 225 (Fig; 21).

This adjusting ring 224 moves longitudinally with movement of the tool body--l8C,-so that .as the cutting edge MC is extended thegend of ad-. justing ring 224 strikes an outwardly projecting shoulder 228 on cutter barrel 212 to limit'the.

radial depth of the groove. Thus, the radial groove depth is controlled by screwing the adjusting ring 224 farther into or out of the shank the adjusting ring 224 for this purpose. In practice, the groove depth is adjusted by inserting the end of tool body 180 into the bore-in which tool body, this spacing will be equal to the radial depth of the groove which will ,have been 'cut K when further cutting action is prevented by the abutment of ring 224 andv shoulder 228. When the correct setting has been determined, a set screw 234 in threaded engagement witnshank holder 225 may be tightened to lock the adjusting ring 224 in position; an insert 236, of relatively soft material, being slidably positioned within the bore beneath the set screw 234, to prevent damage to the threads of adjusting ring 224.

holder 228, for example, by means of a spanner wrench adapted to fit openings 232 provided inrange of bore diameters that may be accom modated by the tool will be as large as possible. The bearing 380 is secured to the pilot 340 by a lock ring 242 and is sealed against the entrance of chips by a lower chip seal ring 242C and an upper chip seal ring 243.

In order to secure the bearing 38C to the pilot barrel 238, a screw 244 (Fig. 12) extends thru a clearance hole 246 in pilot barrel 23B, across the longitudinal slot 248 in pilot barrel 238, and is in threaded engagement with the pilot barrel on the opposite side of the slot; the entire screw 24:; being recessed beneath the outer surface of barrel 238. Thus, because of the resiliency imparted to barrel 238 by the longitudinal slot 248, which opens into a groove 258 of wider transverse dimension and which opens into the interior of barrel 238, the pilot barrel 238 may be clamped securely to the bearing 380 by tightening the screw 244.

In order to releasably clamp the cutter barrel 2l2 to the pilot barrel 238, a nut block 252 and a clamping pad 254 (see also Fig. 24) are positioned within the longitudinal groove 256 on the inner surface of pilot barrel 238 (Figs. 11 and 12). The clamping pad 254 extends into a peripheral notch 25'! (Figs. 11 and 23) in the outer surface of cutter barrel 242 against which it is pressed by a set screw 258, which is in threaded engagement with the nut block 252 and which extends outwardly into slot 248. As set screw 258 is tightened, clamping pad 254 is forced inwardly against the surface of cutter barrel 2|2, and nut block 252 is forced outwardly against the inner surface of the pilot barrel 238, thus, locking the cutter and pilot barrels securely together. It

- is apparent that, by loosening set screw 258, the

cutter barrel 2E2 and the parts secured thereto can be moved longitudinally with respect to the pilot 34C and the pilot barrel 238; the clamping assembly operated by set screw 258 moving longitudinally, with the cutter barrel 2I2, along the slots 255 and 2 38. Thus, the distance within the bore at which the groove is to be cut can be adjusted readily by gauging the distance between pilot shoulder 52C and cutting edge [40 and tightening screw 258 to maintain this adjustment.

In order that the grooving tool may be adjusted for cutting grooves in bores of various diameters, the tool body l8C is mounted in eccentricrelationship within the cutter barrel H2,

and the cutter barrel 2 I 2 is mounted in an eccentric or off-center relationship with respect to the pilot 34C and pilot barrel 238. With this arrangement, by rotating the cutter barrel 2l2,

with respect to the pilot barrel 238 (see-Fig. 12),

the cutting edge may be placed at any desired radial distance from the longitudinal center-line of the cutter barrel 238, and thus from the longitudinal axis of the bore in which a groove is to be out. This is accomplished by rotating the cutter barrel 2|2, for example, by

means of a suitable tool inserted in opening 262 or 254 (Figs. 11 and 14), until the radial position of cutting edge MC corresponds to the diameter of the bore which is to be grooved. This'adjustment-need not be made with precision'be-- cause the groove depth adjustment; (described above) which should be made subsequently to this bore diameter adjustment, will correct automatically for slight error in the bore diameter adjustment. In order to assist in this radial adjustment, a scale generally indicated at 265 (Fig. 14) is inscribed on the upper surface of pilot barrel 238 and is calibrated in conjunction with a longitudinal scale mark 298 (see also Fig. inscribed on the outer surface of cutter barrel 2I2. Thus, the radial adjustment may be made quickly and accurately merely by rotating the cutter barrel until the scale mark 298 indi cates the desired bore diameter.

It is apparent also that the tool body I86 must be rotated about its own longitudinal axis with respect to the cutter barrel 2l2, when the radial adjustment is made, in order that the cutting blade 12C will be directed radially with respect to the bore that is to be grooved. This adjustment is maintained automatically, in this embodiment, by means of the following described structure.

The upper end of the tool body extension M6 is provided with a transverse groove 272 (Figs. 11, 15, 1'7 and 21) having an enlarged portion 274 forming a raceway for a steel ball 216 which is carried by a transverse hole 218 in a key exten sion 282 on the lower surface of a shank 284.

This shank 284 is secured within the shank holder 225 by means of a shoulder 234 (Fig. 11) and friction blocks 238, for example, formed of brass or similar material, which are forced against a beveled face 298, on shank 284, by set screws 292 which are in threaded engagement with the shank holder 226.

Thus, when set screws 292 are loosened slightly and the cutter barrel 212 rotated, the shank 284, which is keyed slidably to the eccentrically positioned tool body 19C; will cause the pilot body I80 to rotate in such manner that the cutting blade I 2C will be directed always radially with respect to the bore in which the groove is to be cut. This follows from the fact that the bore, the pilot 34C, and the shank 284, have a common axis; the key extension 282 always being aligned radially with respect to this axis and, therefore, the cutter blade IZC, which is held by the pilot 180, can rotate only as permitted or caused by the shank 284 and key 232. In order to limit the amount by which the cutter barrel 212 may be rotated during the radial adjustment, a cross pin 294 (Fig. 16) is provided which extends on each side of the shank 284 and impinges against the friction blocks 286. When this radial adjustment has been completed, the set screws 292 are tightened to restore the rigidity of the structure.

In order to maintain proper alignment of the various components of the tool2, guide pillars 295 and 298 (Figs. 17 and 18) are provided, which are press-fitted into shank holder 226 and extend downwardly into openings 392 and 394, respectively, in pilot barrel 238; an opening 396 being provided at the bottom of each of the holes 392 and 394 to permit the passage of air during assembly or adjustment of the tool.

It is understood, of course, that when the tool is to be used with a different diameter of bore that the pilot 340 must be changed in accordance with the size of the bore. For example, Fig. shows a pilot 34D inserted in the tool for grooving a bore of smaller diameter than that shown in the other figures.

I claim:

1. In a grooving tool for cutting internal grooves in bores, the combination comprising a tool body having a longitudinal slot therein, a housing surrounding a portion of said body and keyed thereto for rotary movement therewith and for longitudinal movement with respect thereto, a flat cutting blade positioned along said slot and having a laterally-extending groovecutting edge at one end and a T-shaped head at the opposite end the upper surface of which forms an angle of less than ninety degrees with respect to the longitudinal axis of said body, said blade being pivotally anchored to said housing, a cam surface associated with said blade and tool body for applying a rotary force to said blade upon relative longitudinal movement therebetween to cause said cutting edge to extend from said slot, and a blade retracting compression spring surrounding said body and bearing upon said housing and said upper surface of said T- shaped head thereby to tend to separate axially said body and said housing and to rotate said blade so as to retract said cutting edge.

2. A grooving tool for cutting internal grooves within a bore, comprising a tool body having a longitudinal slot therein, a housing surrounding said tool body and adapted for longitudinal movement with respect thereto, a flat groove-cutting blade positioned in said slot and having a lateral projection at one end and a laterally projecting groove cutting edge at the opposite end, said blade being secured for pivotal movement about said projection with respect to said housing and for longitudinal movement with respect to said tool body, said projection being comprised in a T-shaped portion of said blade, said T-shaped portion forming an end'surface of said blade extending at an angle or" less than ninety degrees to the longitudinal axis of said blade, a cam surface positioned near said cutting edge and extending at an angle to the longitudinal axis of said tool body for translating relative longitudinal movement between said blade and said body into pivotal movement of said blade about said projection to cause said cutting edge to move transversely of said slot, a spring bearing against said end surface of said blade and tending to force said cutting edge inwardly of said slot in said tool body, and a pilot surrounding said tool body and rotatably supported with respect to said housing.

GEORGE H. LEONARD.

REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 614,672 Sweigart Nov. 22, 1898 869,628 Fleming Oct. 28, 1907 1,312,737 Krueger Aug, 12, 1919 1,331,322 Connell Feb. 17, 1920 1,922,630 Oberhuber Aug. 15, 1933 2,224,480 Kartarik Dec. 10, 1940 2,325,020 Shaw July 20, 1943 2,359,859 Jarvis Oct. 10, 1944 2,365,549 Haynes Dec. 19, 1944 2,433,976 Babka Jan. 6, 1948 FOREIGN PATENTS Number Country Date 569,241 Great Britain May 14, 1945 

